The Mechanics of breathing Flashcards
Define resistance
Resistance is an opposing force that acts to reduce the flow of a gas or fluid through a conduit (pipe).
How is resistance generated in the airways?
As air passes through airways, it generates resistance as it comes into contact with the airway surface.
What is the equation for airflow?
Airflow (V) = Pressure (P) / Resistance (R)
Why might we not be able to increase airflow?
We can increase airflow; however this can sometimes not happen e.g the effort/force required to do so may not be able to be generated, or the airway might be completely obstructed.
What factors determine the level of resistance?
- The cross-sectional area of the airway lumen (the empty section in the middle of the airway, through which air passes).
- The airflow patterns.
What does the Hagen-Poiseuille equation describe?
What is the equation?
The relationship between resistance and the various properties of airways and airflow.
Resistance (R) is proportional to 1/ Radius^4
Describe some aspects of respiratory diseases that generate pathological features which reduce the size of the lumen of the airway
Contraction of airway smooth muscle, excessive mucus secretion, oedema/swelling of the airway tissue, and damage to the integrity of the airways structure (i.e. loss of patency) will all reduce the size of the airway lumen, increasing airway resistance and decreasing airflow.
Describe what happens when airflow changes of linear from turbulent and how it impacts on airflow
- Where airflow changes from a linear to a turbulent pattern, increased airway resistance is generated.
- Turbulence occurs where high velocities of airflow are achieved (e.g. during forced breathing manoeuvres) or if there is a sudden decrease in luminal area such as in obstructed airways.
- The vibration generated by the turbulent airflow is responsible for the wheezing sound produced in patients with obstructed airways.
Define airway patency
Patency refers to the state of being open or unobstructed; a ‘loss of patency’ = closing/obstruction
What maintains the open structure of the airway?
The open structure of the airways is maintained by elastic fibres within the wall of the airway and radial traction. Most airways are positioned within surrounding lung tissue which has elastic properties - the airways are pulled open by their connections to the surrounding tissue
In terms of collapsing forces what occurs during forced expiration and what prevents lung collapse during healthy individuals
• When intrapleural pressure becomes positive (as can occur during forced expiration), collapsing force will be exerted onto the airways. In healthy individuals, the structural integrity of the airways is sufficient to prevent collapse, however in diseases involving impaired airway structure (e.g. COPD), this can be problematic .
What is transpulmonary pressure and what does it determine?
The difference between the pressure within the alveoli and intrapleural space (termed ‘transpulmonary pressure) determines the level of force acting to expand or compress the lungs.
What happens with a high lung compliance?
Higher lung compliance = less elastic recoil = less force required to inflate = ↑ volume change per pressure change (↑gradient on volume-pressure curve)
What happens with a low lung compliance?
Lower compliance = more elastic recoil = more force required to inflate = ↓volume change per pressure change (↓ gradient on volume-pressure curve)
What is the equation that links lung compliance, volume and pressure
Compliance (Cl) = change in volume/ changes in pressure
